Ethylene preparation and its application to physiological experiments

Ethylene is the first identified gaseous hormone regulating many aspects of plant growth and development. ACC and ethephon are two widely used chemicals replacing ethylene treatment when ethylene is not available. However, the amount of ethylene converted by ACC and ethephon is not controllable, leaving it questionable whether either treatment can mimic the effects of ethylene for experiments that are sensitive to ethylene concentration, response window, and treatment durations. Ethylene can be chemically made by ethanol dehydration; however, further purification from the dehydration products is needed. We previously reported that the ethylene gas can be easily prepared by decomposing ethephon in a buffered condition and the resulting ethylene can be used directly. Ethylene responses can be estimated by the measurement of the hypocotyl length of etiolated seedlings, or by ERF1 (Ethylene Response Factor1) expression. Although ACC of low concentrations is insufficient to induce ERF1 expression, ACC of high concentrations can replace ethylene for experiments where ethylene treatment is not feasible. However, ACC may undergo early consumption. Versatile approaches were developed so that laboratories lacking ethylene and techniques for gas handling can easily perform necessary ethylene treatments.Key words: ethylene preparation, ethephon, ACC     

Developing tools for investigating the multiple roles of ethylene: identification and mapping genes for ethylene biosynthesis and reception in barley

The plant hormone ethylene is important to many plant processes from germination through senescence, including responses to in vitro growth and plant regeneration. Knowledge of the number and function of genes that are involved in ethylene biosynthesis and reception is necessary to determine the role of specific genes within gene families known to influence ethylene biosynthesis and other aspects of ethylene function in plants. Our objective was built on previous studies that have established the critical role of ethylene in the in vitro response of barley (Hordeum vulgare L.), and that have identified ethylene-related QTL in the barley genome. In this study, we have identified the locations of genes in the barley 1-aminocyclopropane-1-carboxylic acid (ACC) synthase (ACS), ACC oxidase (ACO), and ethylene receptor (ETR) gene families. Specific primers for PCR amplification of each gene were developed and used to map these genes in the Oregon Wolf Barley mapping population. Five ACS, 8 ACO, and 7 ETR genes were identified and mapped to six of the barley chromosomes. Gene locations were syntenous to the orthologs in rice except for two that mapped to chromosome 6H. Gene duplication was evident for ACO genes on chromosomes 5H and 6H. Gene-specific primers will be useful for determining expression of each gene under various environmental conditions, including in vitro environments, to better understand the role of ethylene. Of the six known QTL for green plant regeneration in barley, three were located near the genes mapped in this study.     

Role of ethylene in stimulating stylar abscission in pistil explants of lemons

Abscission in styles of excised Citrus limon (cv. Lisbon) pistils was stimulated by addition of 70 μ M 2-chloroethylphosphonic acid (ethephon) or 0.1 m M 1-aminocyclopropane-1-carboxylic acid (ACC) to the defined medium of cultures. To study the relationship between ethylene and abscission, we used gas chromatography to analyze ethylene in cultures containing a test medium plus or minus abscission-active chemicals. In the presence of ethephon or ACC, ethylene levels in sealed tubes increased rapidly, suggesting that these compounds stimulated abscission because they were converted to ethylene. In the presence of test medium or the inhibitor of abscission 2 μ M picloram, the low ethylene levels found in sealed tubes did not differ strikingly in the two treatments. Ethylene production rates measured prior to abscission with test medium or in the presence of picloram were not markedly different either, although picloram completely inhibited abscission. Stylar abscission was delayed but not prevented by 50 μ M aminoethoxyvinylglycine, an inhibitor of ethylene biosynthesis, and by hypobaric conditions (280 mm Hg) which removed ethylene from cultures. We concluded that ethylene is an important factor regulating stylar abscission in vitro and suggest that the inhibitory effect of picloram involves a process other than detectable ethylene production. Our results do not exclude the possibility that picloram affects enodgenous ethylene biosynthesis and/or metabolism and/or tissue retention.     

Role of aminocyclopropane-l-carboxylic acid in ethylene release by distal tissues following localized application of ethephon in Cucurbita pepo

The application of ethephon to a single leaf of Cucurbita pepo L. cv. Trailing Marrow plants caused a huge increase in ethylene production from the treated organ and an increased rate of ethylene production from other parts of the plant. These increases were particularly marked in the shoot apex and expanding leaf. Prior treatment with aminoethoxyvinylglycine (AVG), an ethylene biosynthesis inhibitor, blocked the increased production of ethylene at sites distant from the point of ethephon application. This strongly suggests that the increased ethylene production at these distant sites is due to ethylene biosynthesis and not a result of the translocation of ethylene released by the breakdown of ethephon at the site of application. Assays of 1-aminocyclopropane-l-carboxylic acid (ACC), an ethylene precursor, showed that it increased substantially after ethephon application but was at undetectable levels in the presence of AVG. It is proposed that the application of ethephon stimulates ethylene biosynthesis, but that transport through the plants is effected by ACC which is then converted to ethylene at the shoot apex and leaves.     

Germination strategy of Striga hermonthica involves regulation of ethylene biosynthesis

Ethylene involvement in germination of Striga hermonthica (Del.) Benth., an important root parasitic weed on poaceous crops, was investigated at the physiological and molecular levels. Seeds, conditioned at 30°C for 14 days, were treated with ethylene, ethephon or 1-aminocyclopropane-1-carboxylic acid (ACC). Ethylene consistently induced low germination. Ethephon and ACC effectively stimulated germination at concentrations of 0.01 and 1 m M , respectively. In contrast to ethylene, both ethephon and ACC acted in a concentration-dependent manner. Germination induced by the synthetic strigolactone GR24 was inhibited by aminoethoxyvinylglycine (AVG) and 1-methylcyclopropene. ACC reversed the inhibition caused by AVG. When seeds were treated with GR24 in sealed vials, ethylene concentration in headspace gas increased prior to the onset of germination. Total RNA extracted from germinating seeds 12 h after GR24 treatment was used for PCR-based amplification of cDNA fragments encoding the ACC synthase- and oxidase-active site domains. Two distinct cDNA fragments encoding ACC synthase ( SHACS1 and SHACS2 ) and one encoding ACC oxidase ( SHACO1 ) were cloned and sequenced. Southern analysis suggested that each of the cloned genes was present as a single copy in the genome of S. hermonthica . Northern analyses showed that SHACS1 exhibited a temporal change in expression peaking at 10 h after GR24 treatment, which coincided with a steady increase in ethylene concentration. SHACS2 was expressed at a low level with a similar trend. SHACO1 exhibited a temporal change in expression peaking at 15 days during conditioning, when seed response to GR24 was maximal. In summary, expression of ACC synthase and ACC oxidase genes was found to be responsive to a germination stimulant and to conditioning, respectively. The implications of these findings with respect to germination of S. hermonthica under field conditions are discussed.     

Effect of plant growth regulators on ethylene production, 1-aminocyclopropane-1-carboxylic acid oxidase activity, and initiation of inflorescence development of pineapple

With the development of pineapple [Ananas comosus (L.) Merr.] as a fresh fruit crop, it became common to force inflorescence development with ethephon [(2-chloroethyl)phosphonic acid] or ethylene throughout the year. Environmental induction (EI) of inflorescence development disrupts scheduling of fruit harvest and may cause significant losses if small plants are induced, resulting in fruits that are too small to be marketable. Our objective was to identify plant growth regulators (PGRs) that could inhibit EI. Because circumstantial evidence indicates that EI occurs in response to naturally produced ethylene or changes in plant sensitivity to it, most work was done with PGRs that inhibit ethylene biosynthesis or block ethylene action. The synthetic auxin 2-(3-chlorophenoxy)propionic acid (CPA) was included because in one study it reduced the percentage of EI. GA₃, aminooxyacetic acid (AOA), aminoethoxyvinylglycine (AVG), daminozide [butanedioic acid mono-(2,2-dimethylhydrazide)], and silver thiosulfate (STS) had no effect on EL CPA, paclobutrazol [(2RS,3RS)-1-(4-chlorophenyl)methyl-4,4-dimethyl-2(1h-1,2,4-triazol-1-yl)penten-3-ol], and uniconazole [(E)-(p-chlorophenyl)-4,4-dimethyl-2-(1,2,4-triazol-1-yl)-1-penten-3-ol] delayed or inhibited EI of pot-grown pineapple plants. Uniconazole and paclobutrazol inhibited growth and ethylene production by leaf basal-white tissue, and either or both effects could account for the inhibition of EI. Production of 1-aminocyclopropane-1-carboxylic acid (ACC) was unaffected by these compounds, but the activity of ACC oxidase, which converts ACC to ethylene, was inhibited and probably accounts for the reduced ethylene production by leaf basal-white tissue. CPA stimulated ethylene production by stem apical tissue approximately fourfold relative to the control. ACC oxidase activity and the malonyl-ACC (MACC) content in stem apical tissue were also greater than in the control, indicating that CPA greatly stimulated the production of ACC and its sequestration into MACC. The mechanism by which CPA delayed or inhibited EI is not known. CPA, paclobutrazol, and uniconazole appear to have some potential for inhibiting EI of pineapple. Their effect on yield needs to be determined.Abbreviations ACC oxidase 1-aminocyclopropane-1-carboxylic acid oxidase - CPA 2-(3-chlorophenoxy)propionic acid - AOA aminooxyacetic acid - AVG aminoethoxyvinylglycine - daminozide butanedioic acid mono-(2,2-dimethylhydrazide) - DM dry mass - ethephon [(2-chloroethyl)phosphonic acid] - FM fresh mass - GA gibberellin - EI environmental induction of inflorescence development - IA inflorescence appearance - LSD Fisher's protected least significant difference - MACC malonyl-ACC - NAA naphthaleneacetic acid - PGR plant growth regulator - paclobutrazol (2RS,3RS)-1-(4-chlorophenyl)methyl-4,4-dimethyl-2-(1h-1,2,4-triazol-1-yl)penten-3-ol] - uniconazole (E)-(p-chlorophenyl)-4,4-dimethyl-2-(1,2,4-triazol-1-yl)-1-penten-3-ol - STS silver thiosulfate - M-leaf fourth leaf - Ml-L first leaf younger than M-leaf     

Influence of growth retardants on the internode and ethylene production of sunflower plants

The growth-retarding activity of the norbornenodiazetine tetcyclacis and the di-oxanylalkenyl triazole LAB 150 978 as well as the ethylene-forming compounds 2-chloroethyl-phosphonic acid (ethephon) and 1-amino-cyclopropane-l-carboxylic acid (ACC) on stem histogenesis and ethylene production of sunflower plants ( He-lianthus annuus L. cv.Spanners Allzweck) has been studied. The shoot growth of plants hydroponically grown and treated was reduced by the compounds. The shortening in the length of the 1st internode caused by tetcyclacis and LAB 150 978 was mainly induced by inhibition of cell division (the internode possessed fewer cortical cells per cell file). In contrast, ethephon and ACC decreased internode elongation mainly by reducing the rate of cell enlargement.
The ethylene production of sunflower seedlings cultivated on agar nutrient medium rose with increasing concentrations of ethephon and ACC, the shoot length of the plants being progressively reduced.
Tetcyclacis and LAB 150 978 inhibited both the formation of ethylene and shoot growth. It is suggested that in contrast to ethephon and ACC, tetcyclacis and LAB 150 978 do not achieve their growth-retarding effect by influencing the production of ethylene.     

Interorgan translocation of 1-aminocyclopropane-1-carboxylic Acid and ethylene coordinates senescence in emasculated cymbidium flowers

In Cymbidium flowers, emasculation by removal of the pollinia and the anther cap leads within 24 hours to red coloration of the labellum (lip). Lip coloration, being the first sign of senescence in these flowers, has been ascribed to the action of ethylene in the lip. When a small incision in the base of the lip is made prior to emasculation, or when the lip is excised and placed in water within 10 to 15 hours after emasculation, coloration is considerably delayed. This indicates that a coloration-associated factor is moving in or out of the lip. Measurements of ethylene production of excised flower parts, isolated at different times after emasculation, showed an increase only in the central column; the other flower parts, including the lip, did not show a measurable change. In contrast, in situ measurements of the ethylene production of the central column and the remaining portion of the flower revealed a simultaneous increase in all the flower parts following emasculation. Similarly, application of radiolabeled 1-aminocyclopropane-1-carboxylic acid (ACC) to the top of the central column in situ leads to the production of radiolabeled ethylene by all the flower parts. In addition, the ethylene production of isolated lips, measured immediately after excision, was initially high but ceased within 10 to 15 minutes. Treatment of the central column in situ with ethylene or ethephon did not stimulate ACC production but did stimulate lip coloration and this was accompanied by an increased internal ethylene concentration in the lip. The data indicate that endogenously produced as well as applied ACC is rapidly translocated from the site of production or application to all the other flower parts where it is immediately converted into ethylene. By excision of a flower organ, the influx of ACC is prevented, causing a rapid decrease in ethylene production. In addition, it was found that ethylene may also be translocated in physiologically significant amounts within the flower. The roles of ACC and ethylene as mobile senescence or wilting factors in emasculation- and pollination-induced senescence is discussed.     

Further studies of auxin and ACC induced feminization in the cucumber plant using ethylene inhibitors

The present study was designed to establish the role of an essential hormone controlling sex expression in cucumber. A potent anti-ethylene agent, AgNO3, completely inhibited pistillate flower formation caused by IAA, ACC or ethephon. Inhibitors of ethylene biosynthesis, AVG and CoCl2 also suppressed feminization due to exogenous IAA or ACC. Though AVG also suppressed ethephon-induced feminization, this may be due to the second effect of AVG rather than the effect on ACC biosynthesis. These results confirm that ethylene is a major factor regulating feminization and that exogenous auxin induces pistillate flower formation through its stimulation of ethylene production, rather than ACC production.     

Current methods for detecting ethylene in plants

Background

In view of ethylene''s critical developmental and physiological roles the gaseous hormone remains an active research topic for plant biologists. Progress has been made to understand the ethylene biosynthesis pathway and the mechanisms of perception and action. Still numerous questions need to be answered and findings to be validated. Monitoring gas production will very often complete the picture of any ethylene research topic. Therefore the search for suitable ethylene measuring methods for various plant samples either in the field, greenhouses, laboratories or storage facilities is strongly motivated.

Scope

This review presents an update of the current methods for ethylene monitoring in plants. It focuses on the three most-used methods – gas chromatography detection, electrochemical sensing and optical detection – and compares them in terms of sensitivity, selectivity, time response and price. Guidelines are provided for proper selection and application of the described sensor methodologies and some specific applications are illustrated of laser-based detector for monitoring ethylene given off by Arabidopsis thaliana upon various nutritional treatments.

Conclusions

Each method has its advantages and limitations. The choice for the suitable ethylene sensor needs careful consideration and is driven by the requirements for a specific application.Key words: Ethylene, Arabidopsis thaliana, gas sampling, gas chromatography, electrochemical sensing, laser-based detector     

Manipulation of ethylene biosynthesis

The plant hormone ethylene is involved in many plant processes ranging from seed germination to leaf and flower senescence and fruit ripening. Ethylene is synthesized from methionine, via S-adenosyl-L-methionine (SAM) and 1-amino-cyclopropane-1-carboxylic acid (ACC). The key ethylene biosynthetic enzymes are ACC synthase (ACS) and ACC oxidase (ACO). Manipulation of ethylene biosynthesis by chemicals and gene technology is discussed. Biotechnological modification of ethylene synthesis is a promising method to prevent spoilage of agricultural and horticultural products.     

Stimulation of somatic embryogenesis in carrot by ethylene: Effects of modulators of ethylene biosynthesis and action

Endogenous levels of ethylene appeared to he suhoptimal for somatic embryogenesis in a suspension culture of carrot. Low concentrations of 1-aminocyclopropane-1-carboxylic acid (ACC). 2-chloroethylphosphonic acid (ethephon) and elhylene stimulated embryogenesis whereas higher concentrations were inhibitory. The stimulation by ACC was through its conversion to ethylene. whereas the inhibition by ACC was not. Low concentrations of AgNO₃. an inhibitor of ethylene action, inhibited embryo-genesis but stimulated ethylene production. Aminoethoxyvinylglycine (AVG) and aminooxyacetic acid (AOA). commonly used inhibitors of ACC synthase. inhibited both embryogenesis and ethylene production. However, the inhibition of embryogenesis was not related to the inhibition ote ethylene production. Very low concentrations of AVG stimulated embryo production in a way unrelated to its effect on ethylene production. Salicylic acid and CoCl₂. inhibitors of ACC oxidase in other systems, inhibited embryogenesis but. again, in way(s) unrelated to their inhibition of ethylene production. In fact, low concentrations of salicylic acid stimulated rather than inhibited ethylene production. The results show that in suspension-cultured cells, caution is warranted in the interpretation of results obtained with agents presumed to inhibit ethylene biosynthesis. The stimulation of somatic embryogenesis by ethylene unequivocally shows that the inhibition of embryo development by 2.4-dichlorophenoxyacetic acid (2.4-D) and other auxins cannot be through their stimulatory effect on ethylene production.     

Effect of ethylene on sanguinarine production from Papaver somniferum cell cultures

A Papaver somniferum cell line capable of producing sanguinarine equivalent to 3% of cell dry weight was used to determine if ethylene was involved in signalling the biosynthesis of this alkaloid. A 3.3-fold increase in ethylene emanation from these cell suspension cultures was observed 7 h after elicitation with a Botrytis fungal homogenate. The rate of ethylene release then decreased to near zero after 48 h, suggesting that a pulse of ethylene production may be involved in sanguinarine production. However, sanguinarine biosynthesis was not promoted when either the ethylene precursor, 1-aminocyclopropane-1-carboxylic acid (ACC), or the ethylene releasing agent, 2-chloroethylphosphonic acid (ethephon), was added to the culture. These results strongly suggest that ethylene is not intimately involved in the production of sanguinarine from Papaver somniferum cell cultures or in the transduction of the elicitation event.Abbreviations ACC 1-aminocyclopropane-1-carboxylic acid     

盐胁迫条件下提高内源乙烯对拟南芥幼苗生长和根尖活性氧水平的影响

以模式植物拟南芥（Arabidopsis thaliana）为材料,研究了内源乙烯对幼苗耐盐性的影响。研究结果表明,在施加了浓度为100 mmol·L^-1的NaCl胁迫的基质环境中,野生型拟南芥幼苗的根长和根重都显著减小。在施加外源乙烯利后不仅能够缓解盐胁迫对幼苗根伸长生长的抑制作用,而且能够缓解盐胁迫对幼苗根增重生长的抑制作用。施加外源ACC则只能缓解盐胁迫对幼苗根增重生长的抑制作用,而不能缓解盐胁迫对根的伸长生长的抑制。此外,100 mmol·L^-1 NaCl的胁迫条件下,拟南芥幼苗根尖中ROS水平明显升高,而施加了乙烯利和ACC处理下,幼苗根尖ROS的水平在NaCl胁迫下并没有明显的升高,说明内源乙烯可以调控植物体内的ROS维持在正常的水平,使植物体免受氧化损伤,从而提高了幼苗耐盐性。     

Ameliorative effect of brassinosteroid and ethylene on germination of cucumber seeds in the presence of sodium chloride

Brassinosteroids are a class of plant polyhydroxysteroids with a diverse of functions in plant growth and development, while ethylene is a gaseous hormone involved in regulation of numerous physiological processes. To evaluate the roles of BR and ethylene in seed germination under conditions of salt stress, effects of 24-Epibrassinolide (EBR) and 1-aminocyclopropane-1-carboxylic acid (ACC) on seed germination of cucumber (Cucumis sativus) seeds in the presence of 250 mM NaCl were investigated. Seed germination was significantly inhibited by the presence of NaCl in the incubation medium, and the inhibitory effect was significantly alleviated by addition of EBR and ACC to the incubation medium containing NaCl. There was an increase in ethylene evolution during seed germination and this increase was suppressed by salt stress. The reduction in ethylene evolution from imbibed seeds by salt stress was attenuated by EBR. Salt stress inhibited ACC oxidase (ACO) activity and EBR reversed the salt stress-induced decrease in ACO activity. Salt stress reduced expression of gene encoding ACO (CsACO2), and EBR reversed the salt stress-induced down-regulation of CsACO2. The alleviative effect of EBR on seed germination in the presence of NaCl was diminished by antagonist of ethylene synthesis, aminoethoxyvinylglycine. These results indicate that both ethylene and BR are likely to be associated with suppression of seed germination under salt stress and that the mitigating effect of BR on salt stress-induced inhibition of seed germination may occur through its interaction with ethylene synthesis.     

Polyamine and ethylene interactions in grain filling of superior and inferior spikelets of rice

This study was to test the hypothesis that polyamines (PAs) and ethylene and their interactions may be involved in mediating the post-anthesis development of spikelets in rice (Oryza sativa L.). Six rice cultivars differing in grain filling rate were field-grown, and the changing patterns of PAs and ethylene levels in rice spikelets during the filling and their relations with grain filling rates were investigated. The results showed that inferior spikelets had much greater ethylene evolution rate and 1-aminocylopropane-1-carboxylic acid (ACC) concentration than superior spikelets. Opposite to ethylene production, superior spikelets showed much higher free-spermidine (Spd) and free-spermine (Spm) concentrations than inferior spikelets. Grain filling rate was very significantly and negatively correlated with ethylene evolution rate and ACC concentration, whereas positively correlated with free-Spd and free-Spm concentrations and with the ratio of free-Spd or free-Spm to ACC. Application of Spd, Spm, or aminoethoxyvinylglycine (an inhibitor of ethylene synthesis by inhibiting ACC synthesis) to panicles at the early grain filling stage significantly reduced ethylene evolution rate and ACC concentration, while significantly increased Spd and Spm concentrations, grain filling rate and grain weight of inferior spikelets. Application of ACC, ethephon (an ethylene-releasing agent), or methylglyoxal-bis (guanylhydrazone) (an inhibitor of Spd and Spm synthesis) showed the opposite effects. The results suggest that antagonistic interactions between PAs (Spd and Spm) and ethylene may be involved in mediating grain filling. A higher ratio of free-Spd or free-Spm to ethylene in rice spikelets could enhance grain filling.     

Enhancement of wound-induced ethylene synthesis by ethylene in preclimacteric cantaloupe

Although intact fruits of unripe cantaloupe (Cucumis melo L.) produce very little ethylene, a massive increase in ethylene production occurred in response to excision. The evidence indicates that this wound ethylene is produced from methionine via 1-aminocyclopropanecarboxylic acid (ACC) as in ripening fruits. Excision induced an increase in both ACC synthase and the enzyme converting ACC to ethylene. Ethylene further increased the activity of the enzyme system converting ACC to ethylene. The induction by ethylene required a minimum exposure of 1 hour; longer exposure had increasingly larger effect. The response was saturated at approximately 3 microliters per liter ethylene and was inhibited by Ag⁺. Neither ethylene nor ACC had a promotive or inhibitory effect on ACC synthase beyond the effect attributable to wounding.     

Dependence of in vivo ethylene production rate on 1-aminocyclopropane-1-carboxylic Acid content and oxygen concentrations

1-Aminocyclopropane-1-carboxylic acid (ACC) is aerobically oxidized in plant tissues to form ethylene by ethylene-forming enzyme (EFE). The effect of substrate (ACC and oxygen) concentrations on ethylene production rate by plant tissues was investigated. The K_m value for O₂ in ethylene production varied greatly depending on the internal ACC content. When ACC levels in the tissue were low (below its K_m value), the concentration of O₂ giving half-maximal ethylene production rate ([S]_0.5) ranged between 5 and 7%, and was similar among different tissues. As the concentration of ACC was increased (greater than its K_m value), [S]_0.5 for O₂ decreased markedly. In contrast, the K_m value for ACC was not much dependent on O₂ concentration, but varied greatly among different plant tissues, ranging from 8 micromolar in apple (Malus sylvestris Mill.) tissue to 120 micromolar in etiolated wheat (Triticum aestivum) leaf. Such a great variation was thought to be due to the different compartmentation of ACC within the cells in different tissues. These kinetic data are consistent with the view that EFE follows an ordered binding mechanism in which EFE binds first to O₂ and then to ACC.